Prevention of the dystrophic phenotype in dystrophin/utrophin-deficient muscle following adenovirus-mediated transfer of a utrophin minigene

Duchenne muscular dystrophy (DMD) is a progressive muscle wasting disorder caused by the lack of a subsarcolemmal protein, dystrophin. We have previously shown that the dystrophin-related protein, utrophin is able to compensate for the lack of dystrophin in the mdx mouse, the mouse model for DMD. Here, we explore whether utrophin delivered to the limb muscle of dystrophin/utrophin-deficient double knockout (dko) neonatal mice can protect the muscle from subsequent dystrophic damage. Utrophin delivery may avoid the potential problems of an immune response associated with the delivery of dystrophin to a previously dystrophin-deficient host. Dko muscle (tibialis anterior) was injected with a first generation recombinant adenovirus containing a utrophin minigene. Up to 95% of the fibres continued expressing the minigene 30 days after injection. Expression of utrophin caused a marked reduction from 80% centrally nucleated fibres (CNFs) in the uninjected dko TA to 12% in the injected dko TA. Within the region of the TA expressing the utrophin minigene, a significant decrease in the prevelance of necrosis was noted. These results demonstrate that the utrophin minigene delivered using an adenoviral vector is able to afford protection to the dystrophin/utrophin-deficient muscle of the dko mouse. Gene Therapy (2000) 7, 201-204.     

Enhanced expression of recombinant dystrophin following intramuscular injection of Epstein-Barr virus (EBV)-based mini-chromosome vectors in mdx mice.

Gene transfer by direct intramuscular injection of naked plasmid DNA has been shown to be a safe, simple but relatively inefficient method for gene delivery in vivo. Eukaryotic plasmid expression vectors incorporating the Epstein-Barr virus (EBV) origin of replication (oriP) and EBNA1 gene have been shown to act as autonomous episomally replicating gene transfer vectors which additionally provide nuclear matrix retention functions. Prolonged expression of a LacZ reporter gene and recombinant human dystrophin was shown using EBV-based plasmid vectors transfected into C2C12 mouse myoblast and myotube cultures. Intramuscular injection of EBV-based dystrophin expression plasmids into nude/mdx mice resulted in significant enhancement in the number of muscle fibres expressing recombinant dystrophin compared with a conventional vector. This effect was observed for over 10 weeks after a single administration. These results indicate the potential advantage of EBV-based expression vectors for focal plasmid-mediated gene augmentation therapy in Duchenne muscular dystrophy (DMD) and a range of other gene therapeutic applications.     

Nucleofection of muscle-derived stem cells and myoblasts with phiC31 integrase: stable expression of a full-length-dystrophin fusion gene by human myoblasts.

Ex vivo gene therapy offers a potential treatment for Duchenne muscular dystrophy by transfection of the dystrophin gene into the patient's own myogenic precursor cells, followed by transplantation. We used nucleofection to introduce DNA plasmids coding for enhanced green fluorescent protein (eGFP) or eGFP-dystrophin fusion protein and the phage phiC31 integrase into myogenic cells and to integrate these genes into a limited number of sites in the genome. Using a plasmid expressing eGFP, we transfected 50% of a mouse muscle-derived stem cell line and 60% of normal human myoblasts. Co-nucleofection of a plasmid expressing the phiC31 integrase and an eGFP expression plasmid containing an attB sequence produced 15 times more frequent stable expression, because of site-specific integration of the transgene. Co-nucleofection of the phiC31 integrase plasmid and a large plasmid containing the attB sequence and the gene for an eGFP-full-length dystrophin fusion protein produced fluorescent human myoblasts that were able to form more intensely fluorescent myotubes after 1 month of culture. A nonviral approach combining nucleofection and the phiC31 integrase may eventually permit safe autotransplantation of genetically modified cells to patients.     

Amphiphilic block copolymers promote gene delivery in vivo to pathological skeletal muscles

We reported that amphiphilic block copolymers hold promise as nonviral vectors for the delivery of plasmid DNA, ranging from 4.7 to 6.2 kb, to healthy muscle for the production of local or secreted proteins. To evaluate the efficiency of these vectors to deliver large plasmid DNA molecules to pathological muscles, plasmid DNAs of various lengths were complexed with Lutrol or poloxamine 304 and injected intramuscularly into dystrophic muscles. Lutrol-DNA and poloxamine 304-DNA complexes promoted gene transfer into muscles of the naturally occurring mouse model for DMD (mdx) in a dose- and plasmid DNA size-dependent manner. For small plasmid DNAs encoding reporter genes, this improvement over naked DNA was smaller in mdx than in the wild-type control strain. By contrast, Lutrol enabled us to deliver the large plasmid (16.1 kb) encoding the rod-deleted dystrophin in mdx mouse muscle, whereas the same amount of naked DNA did not lead to dystrophin expression, under the same experimental conditions. Lutrol-treated mdx mice showed the production of dystrophin in large numbers of muscle fibers. More importantly, we also found that expressing dystrophin with Lutrol led to restoration of the dystrophin-associated protein complex. Thus, we conclude that block copolymers constitute a novel class of vectors for the delivery of large plasmid DNA not only to healthy muscles but also to pathological muscle tissues.     

Long-term expression of full-length human dystrophin in transgenic mdx mice expressing internally deleted human dystrophins

One of the possible therapies for Duchenne muscular dystrophy (DMD) is the introduction of a functional copy of the dystrophin gene into the patient. For this approach to be effective, therapeutic levels and long-term expression of the protein need to be achieved. However, immune responses to the newly expressed dystrophin have been predicted, particularly in DMD patients who express no dystrophin or only very truncated versions. In a previous study, we demonstrated a strong humoral and cytotoxic immune response to human dystrophin in the mdx mouse. However, the mdx mouse was tolerant to murine dystrophin, possibly due to the endogenous expression of dystrophin in revertant fibres or the other nonmuscle dystrophin isoforms. In the present study, we delivered human and murine dystrophin plasmids by electrotransfer after hyaluronidase pretreatment to increase gene transfer efficiencies. Tolerance to murine dystrophin was still seen with this improved gene delivery. Tolerance to exogenous recombinant full-length human dystrophin was seen in mdx transgenic lines expressing internally deleted versions of human dystrophin. These results suggest that the presence of revertant fibres may prevent the development of serious immune responses in patients undergoing dystrophin gene therapy.     

Dystrophin expression in host muscle following transplantation of muscle precursor cells modified with the phiC31 integrase

Duchenne muscular dystrophy (DMD) is the most severe muscular dystrophy. It is caused by the absence of dystrophin in muscle fibers. The autologous transplantation of genetically corrected muscle precursor cells (MPCs) is a possible cure for DMD. A non-viral method of genetic modification was tested in this study. The co-transfection (nucleofection) of a phiC31 integrase and a transgene expressing plasmid in MPCs led to an increased stable expression in vitro. The stable expression of a small transgene (eGFP) in muscle fibers was initially demonstrated following the transplantation of the genetically modified cells. The stable expression of a truncated version of dystrophin as well as the full-length dystrophin fused with eGFP was then demonstrated in MPCs obtained from an mdx mice. The transplantation of these cells led not only to the expression of these fusion proteins in muscle fibers but also to the reconstitution of the dystrophin complex. Human MPCs were also genetically modified with a plasmid coding for the full-length human dystrophin gene fused with eGFP and transplanted in severe combined immuno deficient mice leading to the expression of eGFP dystrophin in muscle fibers. This work indicates that cell transplantation after correction of MPCs with phiC31 integrase is a possible approach to treat DMD.     

构建重组肿瘤基因疫苗对肿瘤进展及生存率影响的实验结局

目的 利用 P815肿瘤动物模型观察 IL- 12对肿瘤动物模型抗肿瘤作用的效应. 方法 将小鼠肥大细胞瘤 P815特异抗原基因 P1A克隆到真核表达质粒 pCI- neo中;用 P815细胞对 DBA/2小鼠右腹侧皮下注射,构建 P815小鼠肿瘤模型;以重组基因疫苗单独或与鼠 IL- 12真核表达质粒一起肌肉注射,观察肿瘤的消长、特异细胞毒 T淋巴细胞激活和抗体的生成情况. 结果 重组基因疫苗在体外有很好的表达,注射后细胞毒性 T淋巴细胞(CTL)的杀伤效率为 40%, IL- 12共注射的 CTL杀伤效率达到 60%.免疫后, 30%小鼠的肿瘤出现消退;同 IL- 12共注射则有 50%的小鼠的肿瘤出现消退.两种情况下都不能检测到任何特异抗体的产生. 结论 长期存在的 IL- 12可以持续刺激机体细胞免疫,使肿瘤的生存环境持续恶化,从而达到治疗肿瘤的目的.     

Factors influencing the efficacy, longevity, and safety of electroporation-assisted plasmid-based gene transfer into mouse muscles.

Intramuscular injection of plasmid is a potential alternative to viral vectors for the transfer of therapeutic genes into skeletal muscle fibers. The low efficiency of plasmid-based gene transfer can be enhanced by electroporation (EP) coupled with the intramuscular application of hyaluronidase. We have investigated several factors that can influence the efficiency of plasmid-based gene transfer. These factors include electrical parameters of EP, optimal use of hyaluronidase, age and strain of the host, and plasmid size. Muscles of very young and mature normal, mdx, and immunodeficient mice were injected with plasmids expressing beta-galactosidase, microdystrophin, full-length dystrophin, or full-length utrophin. Transfection efficiency, muscle fiber damage, and duration of transgene expression were analyzed. The best transfection level with the least collateral damage was attained at 175-200 V/cm. Pretreatment with hyaluronidase markedly increased transfection, which was also influenced by the plasmid size and the strain and the age of the mice. Even in immunodeficient mice, there was a significant late decline in transgene expression and plasmid DNA copies, although both still remained relatively high after 1 year. Thus, properly optimized EP-assisted plasmid-based gene transfer is a feasible, efficient, and safe method of gene replacement therapy for dystrophin deficiency of muscle but readministration may be necessary.     

CTLA4Ig delivered by high-capacity adenoviral vector induces stable expression of dystrophin in mdx mouse muscle

Adenoviral (Ad) vector-mediated gene delivery of normal, full-length dystrophin to skeletal muscle provides a promising strategy for the treatment of Duchenne muscular dystrophy (DMD), an X-linked recessive, dystrophin-deficient muscle disease. Studies in animal models suggest that successful DMD gene therapy by Ad vector-mediated gene transfer would be precluded by cellular and humoral immune responses induced by vector capsid and transgene proteins. To address the immunity induced by Ad vector-mediated dystrophin gene delivery to dystrophic muscle, we developed high-capacity adenoviral (HC-Ad) vectors expressing mouse dystrophin driven by the muscle creatine kinase promoter (AdmDys) and mCTLA4Ig (AdmCTLA4Ig) individually, or together from one vector (AdmCTLA4Ig/mDys). We found stable expression of dystrophin protein in the tibialis anterior muscles of mdx mice, coinjected with AdmCTLA4Ig and AdmDys, or injected alone with AdmCTLA4Ig/mDys, whereas the expression of dystrophin protein in the control group coinjected with AdmDys and an empty vector decreased by at least 50% between 2 and 8 weeks after administration. Additionally, we observed reductions in Ad vector-induced Th1 and Th2 cytokines, Ad vector-specific cytotoxic T lymphocyte activation and neutralizing anti-Ad antibodies in both experimental groups that received a mCTLA4Ig-expressing vector as compared to the control group. This study demonstrates that the coexpression of mCTLA4Ig and dystrophin in skeletal muscle provided by HC-Ad vector-mediated gene transfer can provide stable expression of dystrophin in immunocompetent, adult mdx mouse muscle and applies a potentially powerful strategy to overcome adaptive immunity induced by Ad vector-mediated dystrophin gene delivery toward the ultimate goal of treatment for DMD.     

Augmentation of antitumor activity of a recombinant adeno-associated virus carcinoembryonic antigen vaccine with plasmid adjuvant

Recombinant adeno-associated virus 2 (rAAV) vectors have been successfully used for sustained expression of therapeutic genes. The potential of using rAAV as a cancer vaccine vector and the impact of a bacterial plasmid adjuvant on this activity were investigated. C57BL/6 mice received a single intramuscular injection of rAAV expressing the human tumor-associated antigen, carcinoembryonic antigen (CEA). Three weeks later, when CEA expression was optimal, a bacterial plasmid containing methylated DNA motifs was injected into the same muscle. Mice were challenged 1 week later with syngeneic MC38 tumor cells stably expressing CEA. Immunization with rAAV-CEA alone resulted in sustained transgene expression and the elicitation of a humoral immune response to CEA. Cellular immune response, however, was weak, and tumor protection was not significant. In contrast, immunization with rAAV-CEA and the plasmid adjuvant resulted in stronger cellular immune response to CEA and tumor protection. The addition of plasmid adjuvant increased both myeloid dendritic cell recruitment in situ and CEA-specific T-helper-1-associated immune response. These data indicate that robust rAAV transgene expression of a tumor antigen followed by transient plasmid delivery to recruit and activate dendritic cells is an effective method of eliciting antitumor cellular immune responses.     

骨髓间充质干细胞移植治疗Duchenne肌营养不良型mdx小鼠后的肌电图和dystrophin蛋白表达改变

目的 研究骨髓间充质干细胞（MSCs）移植治疗Duchenne肌营养不良（DMD）模型鼠mdx鼠后肌电图改变及dystrophin蛋白表达变化。方法 分离培养正常小鼠MSCs局部肌肉注射移植入DMD模型鼠mdx鼠，数周后观察肌电图改变及dystrophin蛋白表达变化。结果 MSCs移植后mdx鼠肌电图明显改善，dystrophin蛋白阳性表达肌纤维增加明显。结论 MSCs局部骨骼肌肌肉内细胞移植治疗mdx鼠有一定效果。     

Defining strategies to extend duration of gene expression from targeted compacted DNA vectors

Gene transfer complexes containing poly-L-lysine (poly-K) and DNA with ligands directed at the serpin enzyme complex receptor (sec-R) deliver reporter genes to receptor-bearing cells in vivo. Expression lasts for about 30 days, when complexes containing long-chain poly-K are used. Extending the duration of expression would be desirable if correction of genetic defects is the goal. To test whether the mechanism by which expression is extinguished was due to an immune response to the transgene, or the loss of the transgene, we conducted two experiments. In the first, we injected sec-R-targeted lacZ complexes intravenously (i.v.) into mice genetically engineered to express this gene briefly during development. These mice, who should recognize the protein as 'self', also extinguished lacZ expression after 30 days. In a second experiment, we injected immunodeficient animals with sec-R-targeted human factor IX complexes. A similar temporal pattern of expression was observed in Rag-1 -/- mice, in whom expression also extinguished by 40 days. Moreover, factor IX plasmid DNA was detected in the lung and spleen 50 days after injection of complexes, suggesting that not all cells which had taken up the transgene had been destroyed. Thus, the host's immune response to the transgene may not account for the loss of reporter gene expression from these molecular conjugates. We further tested whether repeat administration of sec-R-targeted complexes will be limited by host immune responses. Mice were pre-dosed twice with sec-R-targeted complexes containing lacZ over a 40-day period. We then injected the animals i.v. with sec-R-targeted human factor IX complexes and measured gene expression and antibody production. Although 14 of 36 animals displayed low-titer antibodies to the ligand in targeted complex, expression levels were unaffected compared with virgin dosing. When the complexes were administered three times intranasally (n=10), no antibodies against the complex were detected in blood. Plasma from mice dosed with saline, nontargeted complex or naked DNA did not react with the ligand, ligand-poly K conjugate or targeted complex. All animals exhibiting human factor IX expression developed antibodies to that transgene by 21 days. Thus, at least three repeat administrations of sec-R-directed molecular conjugates are possible, provided that immune responses to the transgene itself are not limiting.     

Intraarterial delivery of naked plasmid DNA expressing full-length mouse dystrophin in the mdx mouse model of duchenne muscular dystrophy

Our previous studies have demonstrated that the intraarterial delivery of naked plasmid DNA leads to high levels of foreign gene expression throughout the muscles of the targeted limb. Although the procedure was first developed in rats and then extended to nonhuman primates, the present study has successfully implemented the procedure in normal mice and the mdx mouse model for Duchenne muscular dystrophy. After intraarterial delivery of plasmid DNA expressing the normal, full-length mouse dystrophin from either the cytomegalovirus promoter or a muscle-specific human desmin gene control region, mdx mouse muscle stably expressed dystrophin in 1-5% of the myofibers of the injected hind limb for at least 6 months. This expression generated an antibody response but no apparent cellular response.     

Restoration of dystrophin expression in mdx mice by intravascular injection of naked DNA containing full-length dystrophin cDNA

Duchenne muscular dystrophy (DMD) is a lethal, X-linked, recessive disease caused by a defect in the dystrophin gene. No effective therapy is available. Dystrophin gene transfer to skeletal muscle has been proposed as a treatment for DMD. However, successful treatment for DMD requires restoration of dystrophin in the affected muscle fibers to at least 20% of the normal level. Current gene transfer methods such as intramuscular injection of viral vector or naked DNA can only transfect a small area of muscle, and therefore is of little clinical utility. We have developed a semisystemic method for gene transfer into skeletal muscle of mdx mice, an animal model for DMD. Naked DNA was injected through the tail artery or vein of mice, in which the aorta and the vena cava were clamped at the location just below the kidneys. The DNA solution was thus forced into the blood vessels of both legs. Luciferase gene expression was detected in all muscle groups in both legs. The effects of injection speed, injection volume, and ischemia time on gene expression were also optimized. LacZ staining was used to check the spread of gene expression in muscle. Although the percentage of transfected fibers was modest (approximately 10%), beta-galactosidase was found in all muscle groups of both legs. Finally, plasmid DNA encoding full-length dystrophin gene was injected into mdx mice and widespread restoration of dystrophin protein was observed in all muscles of both hind limbs. In conclusion, these results demonstrate that the semisystemic delivery of naked DNA is a potential approach towards the long-term goal of gene therapy for DMD.     

IL-12 plasmid-enhanced DNA vaccination against carcinoembryonic antigen (CEA) studied in immune-gene knockout mice

Intramuscular (i.m.) injection of a plasmid encoding human carcinoembryonic antigen (CEA) elicited immunity against transplanted syngeneic (C57BL/6) CEA-positive Lewis lung carcinoma (CEA/LLC) cells, but tumors still appeared in all mice. In wild-type mice, coinjection of an IL-12 plasmid markedly enhanced anti-CEA humoral, T-helper-1 and cytotoxic T lymphocyte (CTL) responses, and resistance to a CEA/LLC tumor challenge such that 80% of mice remained tumor free. Injection of the IL- 12 plasmid alone was not protective. To analyze immune requirements, we immunized gene knockout (KO) mice of C57BL/6 background, deficient in either CD3, CD4, CD8, interferon gamma (IFNgamma), perforin or Fas ligand (FasL). Only CD3+ mice expressing both CD4 and CD8, which appear equally important, as well as IFNgamma and perforin, could fully resist a tumor challenge. IL-12 stimulated CTL activity, which was strictly CD3/CD8/perforin-dependent. FasL-KO mice had normal CTL activity and tumor resistance, indicating that only the perforin lytic pathway was involved. CD4-KO and IFNgamma-KO mice still generated CTLs. CEA-stimulated IFNgamma production occurred in both CD4- or CD8-KO mice and in both cases was augmented by IL-12. In IFNgamma-KO mice, IL-12 still enhanced anti-CEA antibody production but only moderately restored impaired DTH and tumor resistance. We conclude that the immune requirements for tumor rejection are stringent, involving multiple mechanisms which are all enhanced by IL-12.     

Matching host muscle and donor myoblasts for myosin heavy chain improves myoblast transfer therapy

Intensive efforts have been made to develop an effective therapy for Duchenne muscular dystrophy (DMD). Although myoblast transplantation has been found capable of transiently delivering dystrophin and improving the strength of the injected dystrophic muscle, this approach has been hindered by the immune rejection problems as well as the poor survival and limited spread of the injected cells. In the present study, we have investigated whether the careful selection of donor myoblasts and host muscle for the myosin heavy chain expression (MyHCs) plays a role in the success of myoblast transfer. Highly purified normal myoblasts derived from the m. soleus and m. gastrocnemius white of normal mice were transplanted into the m. soleus (containing 70% of type I fibers) and gastrocnemius white (100% of type II fibers) of dystrophin deficient mdx mice. At several time-points after injection (10, 20 and 30 days), the number of dystrophin-positive fibers was monitored and compared among the different groups. A significantly higher number and better persistence of dystrophin-positive myofibers were observed when the injected muscle and donor myoblasts expressed a similar MyHC in comparison with myoblast transfer between host muscle and donor myoblasts that were not matched for MyHC. These results suggest that careful matching between the injected myoblasts and injected muscle for the MyHC expression can improve the efficiency of myoblast-mediated gene transfer to skeletal muscle. Gene Therapy (2000) 7, 428-437.     

Local and distant transfection of mdx muscle fibers with dystrophin and LacZ genes delivered in vivo by synthetic microspheres.

Patterns of dystrophin and beta-galactosidase expression were examined in mdx mice after i.m. injections of synthetic microspheres (MF-2) loaded with full-length (pHSADy) or mini-dystrophin gene (pSG5dys) cDNA plasmid constructs or with LacZ marker gene (pCMV-LacZ). A single injection of 25 microg pHSADy into quadriceps femoris muscle resulted in 6.8% of dystrophin positive myofibers (DPM) in a given muscle; 8.4% of DPM in glutaeus muscle and 4.3% of DPM in quadriceps femoris muscle of contralateral limb on day 21 after exposure compared with only 0.6% DPM in intact (non-injected) mdx mice. A high proportion of DPM (17.6% and 10.8%, respectively) was registered in both injected and contralateral muscles after mini- gene cDNA administration. MF-2/dystrophin cDNA particles were detected by FISH analysis in about 60-70% of myofiber nuclei in muscles of injected and contralateral limbs 7 days after application. The presence of human dystrophin cDNA and its products in all skeletal muscles and in different internal organs was proven by PCR and RT-PCR analysis. Patches of beta-galactosidase expression were abundant in injected muscle, and frequent in the contralateral and other skeletal muscles as well as in diaphragm, heart and lungs. High levels of dystrophin cDNA expression, and an efficient distant transfection effect with preferential intranuclei inclusion of MF-2 vehicle, are very encouraging for the development of a new constructive strategy in gene therapy trials of DMD.     

In vivo evaluation of an EIAV vector for the systemic genetic delivery of therapeutic antibodies

Lentiviral-based vectors hold great promise as gene delivery vehicles for the treatment of a wide variety of diseases. We have previously reported the development of a nonprimate lentiviral vector system based on the equine infectious anaemia virus (EIAV), which is able to efficiently transduce dividing and nondividing cells both in vitro and in vivo. Here, we report on the application of EIAV vectors for the systemic delivery of an antibody fusion protein designed for the treatment of cancer. The therapeutic potential of a single chain antibody against the tumour-associated antigen, 5T4, fused to immune enhancer moieties has been demonstrated in vitro and here we evaluate the genetic delivery of a 5T4 scFv fused to B7.1 (scFvB7) using an EIAV vector. The kinetics and concentration of protein produced following both intravenous (i.v.) and intramuscular (i.m.) administration was determined in immune competent adult mice. In addition, the immune response to the EIAV vector and the transgene were determined. Here, we show that a single injection of EIAV expressing scFv-B7 can give rise to concentrations of protein in the range of 1-5 microg/ml that persist in the sera for more than 50 days. After a second injection, concentrations of scFv-B7.1 rose as high as 20 microg/ml and levels greater than 2 microg/ml were present in the sera of all mice injected i.v. after 210 days despite the detection of antibodies against both the transgene and viral envelope for the duration of this study. These results demonstrate the potential of EIAV as a gene therapy vector for long-term production of therapeutic recombinant proteins.